Objective: Evaluation of peripheral arterial disease with 64-detector multi-slice CT angiography (MDCT- A) and comparison of the results with the results of digital subtraction angiography (DSA), a standard reference. Materials and Method: The written informed consent of the patients and ethics committee approval were obtained. The retrospective study group consisted of 28 patients with a diagnosis of peripheral arterial disease. Using 64-MDCT-A, the arterial tree of the lower extremity was evaluated for the presence of steno-occlusive lesions that might have led to luminal stenosis. The diagnostic reliability of 64-MDCT- A was calculated and compared with that of DSA. Findings: In the segment-based analysis, the sensitivity, specificity, and reliability rates of 64-MDCT angiography in determining significant stenoses were 97.7%, 97%, and 97.3%, respectively. The Kappa co-efficiency for compatibility between 64-MDCT-A and DSA methods in grading stenosis was calculated as 0.896 (P < 0.001) and it was statistically significant. Conclusion: 64-MDCT angiography is significantly compatible with DSA method in the evaluation of peripheral arterial diseases. It is a non-invasive method and can be an alternative to DSA.
Peripheral arterial disease (PAD) is briefly defined as the atherosclerosis of the arteries other than the coronary arteries. The arteries of the lower extremity are the most commonly involved arteries; thus, the arteriosclerotic obstructions of the distal aorta and arteries of the lower extremity are the most common forms of PAD [
The clinical use and popularity of 64-MDCT angiography has been increasing, but literature reveals limited number of studies using this imaging method in the evaluation of peripheral arterial diseases of the lower extremity and its correlation with DSA method. Therefore, in this study, entire arterial tree of the patients with peripheral arterial disease, including the distal aorta and distal pedal arteries, was evaluated through 64-MDCT angiography and the correlation of the findings with DSA was investigated.
We retrospectively evaluated the usefulness of 64- MDCT angiography in evaluating peripheral arterial occlusive disease compared with DSA.
Before the study was initiated, all the patients included in the study were informed of the study protocol in detail and their written consents were obtained. The study protocol was also approved by the institutional ethics committee.
Between June 2007 and March 2009, 105 patients were evaluated by MDCT angiography with a prediagnosis of PAD. Of this group, enrolled in the study, 77 were excluded: 42 had declined to undergo DSA on the basis CT angiographic findings, 13 had acute ischemia that required immediate treatment, 10 had impaired renal function (creatinine clearance <30 ml/min), and 12 had not come to our institution after CT angiographic examination. Thus, 28 patients were considered to be candidates for either surgical or radiological intervention and then, they were evaluated by DSA method. Of the patients that comprised the study group (n = 28), 27 were male and 1 was female. The mean age of the patients was 62.6 years (Range: 41 - 82 years), All the patients were symptomatic. According to Rutherford classification, of the patients, 5 belonged to category 3; 9 belonged to category 4; 11 belonged to category 5, and 3 belonged to category 6. Seventeen of the patients with vascular risk had type 2 diabetes mellitus; 23, hypertension, 18, hypercholesterolemia, and 21, a smoking habit. One of the patients had chronic renal failure and was on hemodialysis treatment. The renal function test results of the remaining 27 patients were within normal limits (serum creatine <1.3 mg/dl). Two patients had been amputated at the level of the knee joint of the left lower extremity.
For the evaluation of the lower extremity arteries, 64- detector multi-sliced CT (Toshiba Aquilion, Toshiba Medical systems, Tokyo, Japan) was used. All the patients were placed in supine position and in a neutral position with their feet in the gantry first. The area evaluated was between the suprarenal aorta and the tip of the foot. The scanning parameters were set as follows: tube voltage: 120 kv; effective tube flow: 250 mAs, rotation time: 0.4 sec, table speed: 29 mm/s; pitch: 0.844 mm; section thickness: 0.5 mm, and reconstruction interval: 0.5 - 1 mm. To achieve optimal contrasting in the vascular structures, automatic bolus tracking was used in the determination of the delay time. At the level of the renal artery orifice, ROI was placed. After the injection of low-dose contrast material, scanning was automatically started when the density in the abdominal aorta reached the level of 180 HU. Because the device can only process 1500 sections, the scanning was realized in two stages. In the first stage, the abdominal aorta and above the knee level, and in the second stage, the area between below-the-knee and the tip of the foot were evaluated. For each patient, 130 ml contrast material was used. After infusion of the 20 ml saline solution, the contrast material was infused in biphasic fashion, i.e. 40 ml was given at a rate of 5 ml/sec, and the remaining 90 ml, at a rate of 4 ml/sec. After the contrast matter use, 21 cc saline was infused to wash out the veins.
Catheter angiography was performed using a digital subtraction angiography device (Philips Integris, the Netherlands and Siemens artis FA, Germany). All the patients were evaluated through DSA within 6 weeks (1 - 40 days) of MDCT evaluation.
In all the patients, the arterial catheterization was achieved by Seldinger method using a 4-French pigtail catheter. In 26 patients, the catheter was inserted into the superior aortic bifurcation through transfemoral approach, and in 2 patients, because of the presence of Leriche’s syndrome (occlusion extending from the aortic bifurcation to the proximal arteries), it was inserted into the ascending aorta through transbrachial approach.
The CT images obtained were transferred onto the workstation (vitrea), and the data were processed by using maximum intensity projection (MIP), multiplanar reformatting (MPR), CPR (curved multiplanar), and volume rendering (VR) techniques. All the arterial segments, particularly the axial segments, were studied based on MPR (multiplanar reformat) images. The grading was made using all the algorithms. Two radiologists interpreted the images in the computer medium. MIP and VR reconstructions were formed by removing the bone structures semiautomatically and using the 3D function of the work-station.
Because of the proximity between the arteries and bone structures at the foot and ankle level, the evaluation was made without the removal of the bone structures.
In the DSA, all the arterial segments, including the distal aorta and proximal foot segments, were imaged in the posteroanterior projection. DSA images were interpreted two radiologists. In the presence of incompatible findings, a consensus was reached. The radiologists were blinded to the MDCT findings.
The stenoocclusive lesions in the main arterial segments were graded by CTA and DSA. The maximum number of segments evaluated for each patient was 25. These segments were the distal abdominal aorta, mainexternal-internal iliac arteries, main-deep-superficial femoral arteries, popliteal arteries, anterior-posterior tibial arteries, peroneal arteries, dorsalis pedis arteries, and plantar arcus.
All the lesions were evaluated using a 5-point scale depending on the stenosis in the lumen diameter. The stenosis in the lumen diameter were measured by visual observations, using a ruler when needed (DSA), and electronic measurements (CTA). The points in the scale represented the following: grade 0, normal arterial lumen and regular arterial wall; grade 1, mild stenosis, irregularities in the arterial wall, and less than 50% stenosis in the arterial diameter; grade 2, moderate stenosis and 50% - 74% stenosis in the arterial diameter; grade 3, severe stenosis and 75% - 99% stenosis in the arterial lumen, and grade 4, occlusion. More than 50% stenosis (≥grade 2) was considered significant. In the presence of multiple lesions within one arterial segment, the stenotic lesion that caused the most significant stenosis was graded.
The statistical analyses were conducted using SPSS 11.5 for Windows (SPSS Incorporation, Chicago, IL, USA).
The diagnostic reliability of CTA in determining significant stenoses (more than 50%, grade 2, 3, 4) was assessed. DSA results were taken as the standard reference, and for each level, the sensitivity and specificity values were found. To evaluate the compatibility between the two methods in grading the stenotic segment, Cohen kappa co-efficiency (Very good (κ > 0.8), good (κ = 0.61 - 0.8), moderate (κ = 0.41 - 0.6), low (κ = 0.21 - 0.4), very low (κ ≤ 0.2)) was calculated.
In all the patients, to achieve sufficient and homogenous vascular contrast during the MDCT angiography procedure, automatic scanning method was used with bolus tracking in calculating the delay time. The images obtained from all the patients were of high quality, facilitating reliable evaluation. However, in 2 patients, delayed contrast passage due to widespread grade 4 occlusions lead to false positive results. None of the patients developed venous contamination.
A total of 688 segments were evaluated by contrast CTA and DSA. In all the patients, there was significant stenosis in at least one segment based on the MDCT angiography and DSA findings. In the CTA, the stenosis in 491 segments were not significant (grade 0-1), while in the DSA, that number was 506. The number of the significant stenotic lesions determined in the CT (grade 2-3-4) was 197, while in the DSA, it was 182. The distribution of the number of stenotic segments according to MDCT angiography and DSA findings has been presented in
The sensitivity and specificity values of MDCT-A for the lower extremity have been shown in
The findings of MDCT-A and DSA were compatible in 191 (97%) of 196 segments. For the abdominal aorta and main iliac arteries, the findings were fully compatible. In by MDCT-A, a total of 4 nonstenotic segments in the external and internal iliac arteries were evaluated as highgrade, and one significant stenotic segment in the internal iliac arteries was evaluated as low-grade. The sensitivity and specificity of CT in determining the significant stenoses in the aortailiac arteries were 97% and 98% respectively. The compatibility (Kappa value) between the two methods was calculated as 0.910.
The MDCT-A and DSA findings were compatible in 217 arteries out of 222. While by CTA, 3 segments with no significant stenoses in the superficial femoral, deep femoral, and popliteal arteries were evaluated as high grade, and one significantly stenotic segment in the su-
perficial femoral artery was evaluated as low grade. The sensitivity and specificity of CT in determining the significant stenoses were 99% and 98% respectively. The compatibility (Kappa value) between the two methods was calculated as 0.940.
The MDCT-A and DSA findings were compatible in 139 arterial segments out of 162. In the CTA, 12 segments with no significant stenosis (1 segment in the anterior tibial artery; 6 segments in the posterior tibial artery, and 5 segments in the peroneal artery) were evaluated as high grade, while 2 significantly stenotic segments in the anterior tibial artery were evaluated as low grade. The evaluation of luminal opening was highly difficult in the crural arteries with smaller diameters because of widespread wall calcifications, and thus, the number false positive values was higher at this level compared to the those of the other arterial segments. The sensitivity and specificity rates of MDCT-A for the crural arteries were 98% and 92% respectively. The compatibility (Kappa value) between the two methods was calculated as 0.856.
The MDCT-A and DSA findings were compatible for 96 segments out of 106. In the CTA, 6 of the 29 significantly stenotic segments, as determined by DSA, were graded incorrectly as low grade, whereas 4 segments out of 77 with no significant stenosis were graded incurrectly as high grade. The sensitivity and specificity of MDCT-A in determining the significant stenosis at this level were 92% and 96%. The compatibility (Kappa value) between the two methods was calculated as 0.813.
In all the segments, CT and DSA were highly compatible in the grading of the stenoses (κ = 0.81 - 1).
The samples of CTA and DSA findings are presented in Figures 2-7.
To determine the proper treatment for PAD cases, determination of the location stenotic segments and the occlusion severity in the iliac and lower extremity arteries is required. DSA, known as a gold standard in diagnosis of PAD, is an invasive method; thus, it presents some risks and limitations [3-5]. MDCT-A has been shown to be reliable in the evaluation of occlusion pathologies in the arteries of the lower extremity, and its clinical use has been increasing. With CT techniques before the advent of MDCT, it was not possible to image the entire arterial tree of the lower extremity with only one injection of the contrast material. Because of relatively slower image gain of single-detector CT device and its low z-axis
resolution, not all the arteries from the renal area to the foot in the lower extremity could be imaged. With the advent of multi-detector CT technique, significant advantages were gained, particularly in scanning time and section thickness, allowing the evaluation of pathologies
in the peripheral arteries.
Literature presents limited number of studies with multi-detector CT on the evaluation of PAD.
In these studies, the sensitivity and specificity of MDCT in determining the stenosis over 50% were reported to be 90.9% - 100% [7-14]. Cernic et al. that compared the 64-MDCT-A results with the results of DSA, a standard reference in the evaluation of stenoocclusive lesions in PAD cases [
With 64-MDCT, shorter scanning time and less contrast material use are provided, by which sufficient arterial contrast is achieved without a venous circulation. Moreover, 64-MDCT provides thinner sections and higher spatial resolution. However, despite the technical advances, determination of optimal timing for arterial opacification with 64-MDCT device is difficult because the time required for arterial opacification depends on the hemodynamic and vascular state of the patient. Accompanying cardiovascular diseases and any flow obstructions at any point between the infrarenal arteries and pedal arteries or aneurysms will delay the opacification of the arterial tree [
In our study, the scanning was realized by determination of the delay time through bolus timing method. The images of all the arterial segments, including the pedal arteries, were of high quality in all the patients including the complex patients (those with Lerisch syndrome and widespread occlusions). None of the patients developed venous contamination. Nevertheless, in two patients with severe unilateral stenooclusive lesions, delayed contrast material passage resulted in false positive findings.
Laswed et al. conducted the only detailed study that focused on the pedal arteries, and reported sensitivity and specificity rates of 91% and 96% for MDCT in evaluations of crural and pedal arteries [
Another disadvantage of CTA is the challenges experienced at times in the evaluation of severely calcified arteries. Ota et al. have emphasized that in the presence of severe calcification, grading of the stenosis is more difficult [
Portugaller et al reported that when volume rendering technique was used alone, the sensitivity and specificity rates in detecting the high-grade stenosis (>75%) were 84% and 78.5% respectively. With the use of MIP, however, the sensitivity and specificity rates were 89% and 74%. In the same study, the best results were obtained by evaluation of the axial images and the sensitivity and specificity rates were found to be 92% and 83% [
In conclusion, 64-MDCT-A is successful in the imaging of peripheral arterial disease of the entire arterial tree of the lower extremity, including the distal pedal arteries, and it can be considered an noninvasive alternative to DSA.